Machine for cutting spiral teeth on conical gear-blanks.



R. B. WEAVER. MACHINE FOR CUlTINGI SPIRAL TEETH 0N GONIGAL GEAR BLANKS.

APPLICATION FILED APR. 13. 1914.

Patented Mar. 30, 1915.

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mil N MIMIWIMIMIINHH IIHHHHHIIHHII L Mmw R. B. WEAVER. MACHINE PoR CUTTING SPIRAL TEETH 0N CONIGAL GEAR BLANKS.

APPLICATION FILED APR.13,1914. L1 38.51 6., Patented Mar. 30, 1915.

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' of r fig-@ge 'UNITED sTATEs raam unica.

ROBERT IB. WEAVER, 0F DETEOIT, MICHIGAN, ASSIGNOR TO THE TIIVIKEN-DETROIT AXIJE COMPANY, 0F DETROIT, MICHIGAN, A CORPORATION 0F OHIO.

MACHINE FOR CUTTING SPIRAL TEETH 0N CONICAL GEAR-BLANKS.

Specification of Letters Patent.

Patented Mar. 311, 1915.

Application led April 13, 1914. Serial N o. 831,412.

T0 all 'whom t1/tay concern.'

Be it known that I, ROBERT B. WEAVER, a citizen of the United States, and a resident of the city ,of '"Detroit, in the. county of Wayne and rState of Michigan, have invented a new and useful Improvement in Machines for Cutting Spiral Teeth on Conical Gear-Blanks, of which the following is a specification.

This invention relates to cutting spiral bevel gears, worm bevel gears, helical bevel gears, spiral and helical crown gears, and the like.

The object of the invention is to produce partly Iin'ished gears or gear blanks suitable for finishing in other machines.

The invention consists in a machine for rapidly cutting teeth for said gears to approximately correct shape, whereby said teeth can be readily finished to correct shape in a more delicate machine.

The'invention further consists in the parts and arrangements hereinafter described, and is defined with more particularity in the claims appended hereto.

In' the drawings accompanying this speciic'ation, Figure 1 is a plan view of a machine embodying' my invention; Fig. 2 is a face view of the spiral cutter; Fig. 3 is a diagram showing the relative positions of the spiral cutter and gear blank during th( operation of cutting the teeth; Fig. -1 is a development of the cam for controlling the angular movement of the cutter spindle toward and away from the gear blank; and Figsf to 9, inclusiveare diagrams showing the relative positions of the two ends of the cutter and the cross-section shape `of the tooth spaces at successive stages of the operation; Fig. 10 is a diagram showing a tooth space and the relative positions of the first and last teeth of the cutter blade with respect to the tooth: space at the beginning or end of each stage of the'operation; and

Fig. 11 is a cross-sectionl on the line 11-11 in Fig. 1 showing the bell crank partly in side elevation. l

Referring to Fig. 1, the machine shown therein comprises a bed plate 11 supported on legs-so as to be clear of the floor. Supported on the bed plate'near one end ther`eof is an angular-ly movable frame plate v12 for supporting the cross slide 13 which care ries the vertically adjustable pedestal bear- `ing 1-4for the' horizontal cutter head spindlel 15. The frame plate 12 is pivoted to the bed plate by a vertical pin 16, and can swing through a small arc in a horizontal plane about the pin as a center. The cutter head 17 is a round disk and is removably secured to the front end of the spindle 15 in any suitable manner. The cutter head carries the spiral cutter 18 upon its front face, the ends of the cutter teeth being at increasing distances from said face around the spiral. The aXis of the cutter head spindle passes behind the pin 16, and the front face of the cutter head is very nearly in line with the axis of the pin. A plane through the cutting points of the longest teeth and at right angles to the axis of the cutter head goes through the axis of the pin. Hence the path of the longest teeth of the cutter lies in a plane through the axis of the pin whatever the angular position of the frame plate 12.

The spiral cutter 1S may be made in the form of a continuous toothed blade, secured to the cutter head in a spiral and with theirpoints at progressively increasing distances therefrom. The cutter blade 18 is of approximately the same shape in cross-section as the normal outline of the tooth space to be out, that is, the outline of the tooth space at right angles to the sides of the teeth. The points of the teeth at the inner end 19 of the blade are closest to the face of the cutter head, and the points of the teeth at the outer end 20 are farthest therefrom; but this arrangement may be reversed provided that the cutter head and gear blank are rotated in the opposite directions from the directions of rotation as shown in Figs. 1, 2 and 3.

1n the arrangement shown in Figs. 1, 2 and 3, the outer end 20 Vof the spiral blade, which cuts the deepest part of the tooth space, is adjusted with its axis of symmetry normal to thel gear blank at the cutting point.` The teeth at the outer end of the spiral are approximately one-third longer than the teeth at the inner end of the spiral to conform to thenumber of stages or suc'- cessive outs required for the completion of the cutting operation. 1f the cutting operation is to be performed in two stages, the long teeth would have to beiifty per cent. longer than the short teeth. vThe inner end of the spiral blank may be made the longest and the direction of rotation of cutter and blank reversed, if desired. The dierence in the radial distances of the inner and outer, ends of the spiral blade from the axis of the cutter head is approximately the same as the circular pitch of the gear which the blade is designed to cut. The spiral blade may be secured to the cutter head in any suitable manner, as by being set into a spiral groove in the front face of the cutter head and held in place by set screws 21.

The plane of the face of the cutter head with respect to the 'axis of the pin 16 may be adjusted by means of the ring nuts 22, threaded on the cutter head spindle 15 and bearing against each end of the pedestal bearing 14. A worm wheel 23 is adjustably secured to the rear end of the cutter head spindle for rotating the cutter head. A worm 24 splined on a vertical shaft 25 meshes with and drives the worm wheel 23.' The vertical shaft 25 is driven by means of a flexible shaft from a suitable countershaft placed on the ceiling above the machine.

The gear blank 26 to be operated upon is mounted upon the end of-a horizontal spindle or arbor 27 slidably arranged in a sleeve 28 rotatably mounted in a pedestal bearing 29 which is bolted to the bed plate. The aXis of the spindle or arbor 27 intersects the axis of the pin 16 at right angles thereto, and the pedestal bearing 29 is adjustable on the bed plate toward and from the pin. The gear blank is clamped to the arbor 27 and sleeve 28 by means of a disk 30 which is removably secured on the end of the arbor outside of the gear blank by means of a spanner ring 31 seated in a circumferential groove around the end of the arbor. The opposite end of the arbor is screw-threaded and projects through the sleeve 28, and a hand wheel 32 with an internally threaded hub is mounted on the projecting end of the arbor and bears against the end of the sleeve. By turning the hand wheel the arbor can be drawn through the sleeve to clamp the gear blank. The gear blank arbor is rotated by a train of gearing at a speed which bears the following ratio to the speed of rotation of the cutter head, namely, one divided by the number of teeth to be cut in the gear blank. The train of gearing for rotating the gear blank arbor includes a pair of spiral gears 33, 34, mounted one on the lower end of the vertical shaft 25 which is driven from the ceiling, and the other on 'a short horizontal shaft 35 mounted in a bearing block 36 bolted on the cross slide 13. The bearing 36 and shaft 35 are adjustable toward and from the vertical shaft 25, whereby different sets of spiral gears 33, 34 may be used, depending upon the speed ratio of gear blank to cutter head which it is desired to use.

The short shaft 35 on the cross slide 13 is connected by means of universal joints and telescoping shaft sections 37 with a second short shaft 38 which is mounted in bearings secured to the bed plate 11` at the opposite end of the machine from the shaft 35. The short shaft 38 carries a worm 39 which drives a worm wheel 4 0 on a vertical shaft 41 which passes through the bed plate and is mounted in bearings fixed thereto. The upper end of the vertical shaft 41 carries a worm` 42 which drives a worm wheel 43 splined on the sleeve 28y which carries the gear blank arbor 27. The train of gearing between the cutter head spindle and gear blank arbor is such that the cutter head and gear blank are simultaneously rotated in the direction shown by the arrows in Figs. 1 and 3. In order to bring the cutting faces of the teeth of the cutter blade into cutting relation with the gear blank, the frame plate 12 has a sector portion 44 which is angularly adjustable about the pin 16 with respect to the frame plate. The adjustable sector portion 44 is provided with a projecting lug 45 on its edge toward the gearing train which drives the gear blank arbor. This lug 45 has a slot 46, the sides of which are vertical and parallel, forming a slide for an operating pin, whereby the sector and frame plate can be oscillated about the pivot pin 16. A bell crank lever having both its arms horizontally disposed is pivotally mounted on the bed plate opposite the end of the slot 46, the pivot 47 of the lever being in line with the slot at about the middle of the arc of movement of the adjustable frame sector 44. The pivot 47 passes through the bed plate, Aand one arm 48 of the bell crank lever is above the bed plate and extends toward the slot 46, and the other arm 49 is below the bed plate and at approximately right angles to the arm 48. The arm 48 carries a slotted extension 50 with a pin 51 on its end which works in the slot 46 in the frame sector 44. A bolt 52 passing lthrough the slot in the arm extension 50 secures the latter to the arm 48, and enables the extension to be moved lengthwise of the arm for adjusting the radial distance of the pin 51 from the pivot of the bell crank lever.

The lower arm 49 of the bell crank lever carries at its extremity a pin 53 which engages in a circumferential cam slot 54 on a cylindrical cam 55. The cam 55 is mounted on a shaft 56 journaled below the bed plate, and is rotated by means of a train of gearing from the vertical shaft 41 which forms part of the train of gearing which drives thel gear blank arbor. This gearing comprises a spur gear 57 mounted on the shaft 56 and meshing with a spur pinion 58 on a horizontal shaft 59 journaled below the bed plate and carrying a worm wheel 60. The vertical shaft 41 extends down through the bed plate and carries a worm at its lower end, similar to the worm 42. The worm 4 at the lower end of the vertical shaft 41 connected by helical portions leadingin the same direction, so that thel greater part of the' cam'slot Winds around the cam in a broken curvef havingthe general ydirection of a helix. The straight portions at the two ends of'the helix-like portion of the cam slot are'conn'ected by a reverse 'helical por-v tion which extends axially a greater dis'- tance'tha-n the axial displacement fthe initialj straight portion with respect'v to* the terminal straight portion and thenrev'erses its direction: to connect With the end of the initial straight portion. A completerevo- Alution of thecanrin th'e direction ofthe arrow from its position'in Fig; l Willlnove the pin 53 to the left suiliciently to cause the cutter blade .to'engage the gear -blank and cut the full depth of the tooth space, and

then will move the pin' to' the right;l andcause the cutter blade to Withdraw from the `.cut. The depth ofthe cut maybe varied by adjusting the length-of the' extension portionv 50 of the toplever 'arm 48.

The cam 55 and coperating parts ofth'e machine 'are' so constructed and arranged as to feed the `cutter blade from outof cutting` engagement to an" angular position Where it will-cut one-third'y of the depth of the' tooth space and retain it in' this angular'po-` sition yun'tillthe'gear blank has made nearly one" complete revolution and each tooth space is roughed out to one-"third its depth. During they second revolution of the: gear blank the cutter head is heldin angular po'- sition to cut two-thirds the depth of the xtooth space; and during 'the third revolution of the-'gear blankthe cutter head is held in angularp'osition' to cut the 'full depth of the4 tooth space. v

A-development ofthe cam55 is shown in Fig.' 4, the direction of rotation being shown by the arrow. The position of-thecam pin with respect to the cam` corresponding to each offthe-serial stages ofV thc cuttingoperation' shown iny Figs. 5 to 9` is indicated fby" dotted circles vin Fig. 4.

Fig.1 5 shows'the relative positions ofthe inner end-19 and v'outer end 20 ofthe cutter blade with respect to-fthe'gear' blank-26 at the beginning'of-theoperation; v'.l`lua'cani is the gear blank. About three revolutions of the cutter head are required to rotate the cam through the angle between the lines 6 6 and L7 7. The shape ofl the tooth space at-the end ofthe first cutting revolution of the cutter head Will resemble the tooth space a in Fig. 7. During the second cutting revolution of the cutter head about tWothirds'of the teethof the cutter blade will engage the gear-blank,- and the second tooth space` Will be aboutas shown at b in Fig. 7 At'the 'end vof the second cutting revolution of'thefcutter head thel cam Will have moved the caInpin laterally from the line 0 0 to the line 1 1, and all the teeth of the -cutter blade will engage the gear blank during the third cutting revolution of the cutter head.y 4The thirdand succeeding tooth sp'a'ces'cut during the first revolution of' 'the gear blank will have the' shape shown at c in' Figs. 7 and 8.

T'oWard the end of the first revolution of the gear blank the relative position of the cam with respect to the pin will approach the line 8 8, and the inclined portion of the slot will engage the pin. At the end of the first revolution of the gear blank the pin will have been moved laterally from the line 1 1'to the line 2 2, and the cutter head Will be fed toward the gear blank for the second cut or stage of the operation, as shown in Fig. 8. The tooth spaces as left bythe cutter blade' after its second cut Will have the shape shown at d in Figs. 8 and 9.' Similarly, toward the end of the second cutting-'stage of the Operation, the relative position ofthe' cam with respect to the pin Wil-l approach the line 9 9, and at-the end of the second revoluticn of the gear blank after the startof thecutting operation, the pin Will have been moved laterally frcm the line 2 2 to the line 3 3 in Fig. 4. At Athis stage the cutter head Willh'ave been fed toward the blank inreadi'ness for the third cut, as'shoyvn in Fig. 9. The tooth spaces as-leftby the cu'tterblade after the third cut,

whichA is the final one, will havev the shape shoWn-^ate in Figs. 9 and 10. Following -the completion of the thirdstageof the cutting operation the earn pin will be 'engaged by,- the inclin'edportion ofthe cam between the'lines 10%--10 and 5 5, and Will be moved laterally back from the line 8 3'to'the line 4 4 at the'istarting point, atwhich poilrttheY cutter blade is completely withdrawn from engagement with the finished gear blank, and the latter may be removed from the arbor. l

It is evident from the preceding description that the-same cutter blade can be used .to rough out lgears having various angles of bevel and numbers of teeth by properly adjusting the position of the cutter head spindle and gear blank arbor and using suitable ratios for the gearing trains, provided the circular pitch is thesame for all the gears to be cut. In adjusting the gear blank arbor, the apex of the conical pitch surface of the gear blank should be brought tocoincide with the axis of the pin 16, which can be done by shifting the pedestal bearing 29 along the bed plate toward or from the pin.

The Worm-wheel 43 can be slid along thesplined sleeve and secured-by a set screw in proper position to mesh with the worm 42. The cutter head spindle should be adjusted axially in its bearing to bring the points of the longest teeth of the cutting blade into a plane passing through the axis of the pin 16 at right angles to the axis of the spindle. The angular adjustability of the sector 44 on the frame plate 12 permits angular adjustment of the plane of the cutter head to suit the angle of bevel of the gear blank. The position of the cutting point of `the cutter blade with respect to the rim of the gear blank can be adjustedto suit the angularity of the helical teeth to be cut, by shifting the cross slide 13 and pedestal 14, which will not aect the position of the plane of the cutting points of the cutter blade teeth. The

depth of the cut can be varied to suit the desired tooth shape by adjusting the length of the extension portion- 50 of the lever arm 48 to give more or less throw to the pin 51 which oscillates the frame 12. For cutting small gears or gears of soft metal it will not be necessary to make the cut in three stages and it is obvious that a cam having a slot with only two, or even only one, .straight portions, can be substituted for the cam 55, in which case the train of gearing which drives the cam will have to be modified also in order to rotate the cam at slightly less than one-half the speed of the gear blank.

toothed articles having curved teeth. The

inventionis also applicable to roughing out gear wheels prior to nishing them with short straight teeth.

Ifclaim the following as my invention:

l. A machine for cutting spiralv bevel gears comprising a rotatablymounted arbor for a gear blank, a rotatably mounted spindle with its axis arranged at an angle to the axis of said arbor and in a plane parallel thereto, a cutter head on said spindle, said cutter -head having cutting teeth arranged in 7'5 the form of a spiral on its face, and means i for rotating said spindle and arbor at a xed velocity ratio.

2. A machine for cutting spiral bevel gears comprising a rotatably mounted arborv 80. for a gear blank, a rotatably mounted spindle with its axis arranged at an angle to the axis of said arbor and in a plane parallel thereto, cutter head on said spindle, said cutter head having cutting teeth l.arranged in the form of a spiral on its face, means for causing relative movement of approach between= said arbor and spindle, and means for rotating said spindle and arbor at a fixed velocity ratio.

3. A machine for cutting spiral bevel gears comprising a rotatably mounted arbor for a gear blank, a rotatably mounted spindle with its axis arranged at an angle to the axis of said arbor,.a cutter head on said spin- 9b dle, said cutter head having cutting teeth arranged in the form of a splral on its face, means for swinging said spindle with respect to saidl arbor for causing relative movement of approach between said cutting teeth and said arbor, and means for rotating said spindle and arbor at a fixed velocity ratio.

4. A machine for cutting spiral bevel gears, comprising a bed plate, a-rotatably mounted arbor for a gear blank supported on said bed plate, a swinging frame pivoted to said bed plate, the axis of the pivot intery.

' secting the axis of said arbor at right angles,

a rotatably mounted spindle carried by said frame with its axis arranged at an angle to the axis of said arbor, a cutter head on said spindle,'said cutter head having cutting teeth arranged in the form of a spiral on its face, means for swinging said frame to cause said '115 teeth to approach said arbor, and means for rotating said spindle and arbor at a fixed velocity ratio.

5. A machine for cutting spiral bevel gears comprising a bed plate, a rotatably mounted arbor for a gear blank adjustably supported on said Y bed plate, a swinging frame pivoted to said bed plate, the axis of the pivot intersecting the axis of said arbor at right angles, a rotatably mounted spindle adjustable in said frame with its axis arranged at an angle to the axis of said arbor, a cutter head on said spindle, said cutter head having cutting teeth arranged in the form of a spiral on its face, means for swinging said frame to cause said teeth to approach said arbor, and means for rotating said spindle and arbor at a fixed velocity ratio.

6. A machine for cuttingV spiral ,bevel gears comprising a bed plate, a rotatably mounted arbor for a gear blank adjustably supported on said bed plate, a two-part swinging frame pivoted to said bed plate, one of said parts being angularly adjustable with respect to the other, and the pivotal axis of both parts intersecting the axis of said arbor at right angles, a rotatably mounted spindle adjustable in said frame with its axis arranged at an angle to the axis of said arbor, a cutter head on said spindle, said. cutter head having cutting teeth arranged in the form of a spiral on its face, means for swinging said frame toV cause said teeth to approach said arbor, and means for rotating said spindle and arbor at a fixed velocity ratio.

7. In a machine for cutting spiral bevel gears, a swinging frame, a spindle rotatably mounted thereon, gearing for rotating said spindle, an arm having a'connection with said frame for holding and swinging it, said arm being provided with a cam follower, a rotatable cam having a groove for said follower, gearing for rotating said cam, and a flexible shaft connecting said spindle gearing and said cam gearing.

8. In a machine for cutting spiral bevel gears, a swinging frame, a spindle rotatably mounted thereon, gearing for rotating said spindle, an arm having a connection with said frame for holding and swinging it, said arm being provided with a cam follower, a rotatable cam having a groove for said follower, said groove having a dwell portion for holding said follower stationary during part of each revolution of the cam, gearing for rotating said cam, and means for rotating said spindle gearing and said cam gearing at a fixed velocity ratio.

9. In a machine for cutting spiral bevel gears, a swinging frame, a spindle rotatably mounted thereon, gearing for rotating said spindle, an arm having a vconnection with said frame for holding and swinging it, said arm being provided with a cam follower, a

rotatable cam having a groove for said follower, said groove comprising a series of dwell portions displaced sidewise with respect to the path of movement of said follower, connected by portions inclined to the path of movement of said follower, gearing for rotating said cam and means for rotating said spindle gearing and said cam gearing at a fixed velocity ratio, whereby said frame is intermittently oscillated and held at rest for definite periods of rotation of said spindle.

l0. In a machine for cutting spiral bevel gears, a journal bearing, a spindle rotatably mounted thereon, a cutter head carried by said spindle, said cutter head. having cutters arranged in a flat spiral curve with their cutting points at increasing distances `from the plane of said spiral, an arbor for a gear blank, and means for rotating said arbor one tooth space of the gear being cut for each rotation of the cutter head spindle.

11. In a machinefor cutting spiral bevel gears, a swinging frame, a spindle rotatably mounted thereon, a cutter head carried by said'spindle, said cutter head having cutters arranged in a fiat spiral curve with their cutting points at increasing distances from the plane of said spiral, an arbor for a gear blank, means for swinging said frame to move said cutter head toward and away from said arbor, and means for rotating said arbor one tooth space 4of the gear being cut for each rotation of the cutter head spindle.

12. In a machine for cutting spiral bevel gears, a swinging frame, a spindle rotatably mounted thereon, a cutter head carried by said spindle, said cutter head having cutters arranged in a flat spiral curve with their cutting points at increasing distances from the plane of said spiral, an arbor for a gear blank, means for intermittently swinging said frame to move said cutter head toward and away from said arbor, and means for rotating said arbor one tooth space of the gear being cut for each rotation of the cutter head spindle.

13. In a machine for cutting spiral bevel gears, a rotatably mounted cutter head, cutting teeth arranged in a fiat spiral on said cutter head, the ends of said spiral being in proximity to each other and at respective distances from the axis of said cutter head such that the difference between said distances is approximately equal to the circular pitch of the gear to be cut thereby, means for continuously rotating a gear blank in front of said cutter head, and means for causing relative movement of said cutter head and. gearblank whereby said cutting teeth are fed into said gear blank.

14. In a machine for cutting spiral bevel gears, a swinging frame, a cam having a continuous groove, a follower engaging in vsaid groove, and positively acting connections between said follower and said swinging frame for imparting movement thereto, said connections comprising sector adjustably secured to said swinging frame and a crank arm connected at its end to said sector, said crank arm being adjustable in length.

15. In a machine for cutting spiral bevel gears, a bed plate, a rotatably mounted arbor for a gear blank carried thereby, a swinging frame pivoted to said bed plate, a rotatably mounted cutter spindle carried by said frame, the axis of said spindle being at an angle to the axis of said arbor, means for swinging said frame comprising a cam mounted for rotation on said bed plate, a movable follower supported on said bed plate and adapted to coperate with said cam, connections between said follower and frame whereby movement of said follower produces like movement of said frame, and gearing between said arbor, said spindle and said cam for rotating them at fixed velocity ratios with respect to one another.

16. In a machine for cutting spiral bevel gears, a bed plate, a rotatably mounted arbor for a gear blank carried thereby, a swinging frame pivoted to said bed plate, a rotatably mounted cutter spindle carried by said frame, the axis of said spindle being at an angle to the axis of said arbor, means for swinging said frame comprising a cam mounted for rotation on said bed plate, a movable follower supported on said bed plate and adapted to coperate with said cam, adjustable connections between said follower and frame whereby movement of said follower produces like movement of said frame, and change gearing between said arbor, said spindle and said cam for rotating them at predetermined ixed Velocity ratios with respect to one another.

17.Y A machine for cutting spiral bevel gears comprising a cutter head mounted for rotation in a plane perpendicular to its axis of rotation and having a series of cutting teeth conforming to the normal shape of tooth space to be cut, said cutting teeth being arranged in a spiral curve andeat varying distances from said plane of rotation of the cutter head.

18. A machine for cutting spiral bevel .gears comprising a cutter head mounted for rotation in a plane perpendicular to its axis of rotation and having a series of `1cutting teeth conforming to the normal' shape of tooth space to be cut, said cutting teeth'being arranged in a spiral curve and at varying distances from said plane of rotation of the cutter head, and means for rotating a gear blank with its periphery normal to said spiral. n

19. A machine for cutting spiral bevel gears comprising a cutter head mounted for rotation in a plane perpendicular to its axis of rotation and having a series of i cutting teeth conforming to the normal shape of tooth space to be cut, said cutting teeth being arranged in a spiral curve and at varying distances, from said plane of rotation of the cutter head, increasing toward one end. of said spiral, and means for rotating a gear blank with its periphery normal to said spiral at a point near the end where the long cutting teeth are located.

20. A machine for cutting spiral bevel gears comprising a cutter head mounted for rotation in'a plane perpendicular to its axis of rotation and having a series of cutting teeth conforming to the normal shape of tooth space to be cut, said cutting teeth being arranged in a spiral curve and at varying distances from said plane of rotation of the cutter head, means for rotating a gear blank with its periphery opposite the path of said cutting teeth, and means for swinging the plane of rotation of said cutter head toward said gear blank.

21. A machine for cutting spiral bevel gears comprising a bed plate, an arbor for a gear blank supported on said bed plate for rotation on an axis parallel thereto, a frame pivotally supported on said bed plate, said frame comprising two parts which are relatively adjustable about its pivotal axis one with respect to the other, a rotatably mounted spindle adjustably supported by said frame with its axis arranged at an angle to the axis of said arbor, a cutter head on said spindle, said cutter head having cutting teeth arranged in the form ofa spiral on its face, means for swinging said frame to cause said teeth to approach said arbor, and means for rotating said spindle and arbor at a fixed velocity ratio.

22. A machine for cutting spiral bevel ears comprising a pivoted frame adapted or oscillatory movement, a spindle rotatably mounted on said frame, means for rotating said spindle, a lever arm provided with a cam follower, an adjustable connection between said pivoted frame and lever arm, a rotatable cam adapted to be engaged by said cam follower, said cam having p0rtions adapted to move said cam follower and intervening portions adapted to hold it stationary, and means for rotating said cam l ROBERT B. WEAVER.

Witnesses LESLIE WmLIAMs, W. C. Woon. 

